Magnetic-field control of interactions in alkaline-earth Rydberg atoms and applications to XXZ models

Abstract

We study the magnetic-field dependence of the interactions between two alkaline-earth(-like) Rydberg atoms, 88Sr and 174Yb. Considering the pair of Rydberg states |ns,3S1,mJ and |(n+1)s,3S1,mJ, we show that the effective Hamiltonian takes the form of an XXZ-type quantum spin model, as in the alkali-atom case [M. Kunimi and T. Tomita, Phys. Rev. A 112, L051301 (2025)]. We find that the behavior of the anisotropy parameter for 174Yb at zero magnetic field is significantly different from that for other atomic species. This behavior originates from the strong spin-orbit coupling in 174Yb. We systematically calculate the interaction parameters of the XXZ model in the presence of a magnetic field and show that they can be tuned by the field. As applications to quantum many-body problems, we investigate one-dimensional systems in the large-anisotropy regime and show that the folded XXZ model can be realized in 174Yb systems without fine-tuning of the field. We also investigate two-dimensional square-lattice systems and show that a supersolid phase can emerge in the ground state at the mean-field level.